/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 2000-2010. All Rights Reserved.
*
* The contents of this file are subject to the Erlang Public License,
* Version 1.1, (the "License"); you may not use this file except in
* compliance with the License. You should have received a copy of the
* Erlang Public License along with this software. If not, it can be
* retrieved online at http://www.erlang.org/.
*
* Software distributed under the License is distributed on an "AS IS"
* basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
* the License for the specific language governing rights and limitations
* under the License.
*
* %CopyrightEnd%
*/
#ifndef __ERL_TERM_H
#define __ERL_TERM_H
#include "sys.h" /* defines HALFWORD_HEAP */
#if HALFWORD_HEAP
# define HEAP_ON_C_STACK 0
# if HALFWORD_ASSERT
# ifdef ET_DEBUG
# undef ET_DEBUG
# endif
# define ET_DEBUG 1
# endif
# if 1
# define CHECK_POINTER_MASK 0xFFFFFFFF00000000UL
# define COMPRESS_POINTER(APointer) ((Eterm) (UWord) (APointer))
# define EXPAND_POINTER(AnEterm) ((UWord) (AnEterm))
# else
# define CHECK_POINTER_MASK 0x0UL
# define COMPRESS_POINTER(AnUint) (AnUint)
# define EXPAND_POINTER(APointer) (APointer)
# endif
#else
# define HEAP_ON_C_STACK 1
# define CHECK_POINTER_MASK 0x0UL
# define COMPRESS_POINTER(AnUint) (AnUint)
# define EXPAND_POINTER(APointer) (APointer)
#endif
struct erl_node_; /* Declared in erl_node_tables.h */
/*
* Defining ET_DEBUG to 1 causes all type-specific data access
* macros to perform runtime type checking. This is very useful
* during development but reduces performance, so ET_DEBUG should
* be disabled during benchmarking or release.
*/
/* #define ET_DEBUG 1 */
#ifndef ET_DEBUG
# ifdef DEBUG
# define ET_DEBUG 1
# else
# define ET_DEBUG 0
# endif
#endif
#if ET_DEBUG
#define _ET_DECLARE_CHECKED(TF,F,TX) extern TF checked_##F(TX,const char*,unsigned);
#define _ET_APPLY(F,X) checked_##F(X,__FILE__,__LINE__)
#else
#define _ET_DECLARE_CHECKED(TF,F,TX)
#define _ET_APPLY(F,X) _unchecked_##F(X)
#endif
#define _TAG_PRIMARY_SIZE 2
#define _TAG_PRIMARY_MASK 0x3
#define TAG_PRIMARY_HEADER 0x0
#define TAG_PRIMARY_LIST 0x1
#define TAG_PRIMARY_BOXED 0x2
#define TAG_PRIMARY_IMMED1 0x3
#define primary_tag(x) ((x) & _TAG_PRIMARY_MASK)
#define _TAG_IMMED1_SIZE 4
#define _TAG_IMMED1_MASK 0xF
#define _TAG_IMMED1_PID ((0x0 << _TAG_PRIMARY_SIZE) | TAG_PRIMARY_IMMED1)
#define _TAG_IMMED1_PORT ((0x1 << _TAG_PRIMARY_SIZE) | TAG_PRIMARY_IMMED1)
#define _TAG_IMMED1_IMMED2 ((0x2 << _TAG_PRIMARY_SIZE) | TAG_PRIMARY_IMMED1)
#define _TAG_IMMED1_SMALL ((0x3 << _TAG_PRIMARY_SIZE) | TAG_PRIMARY_IMMED1)
#define _TAG_IMMED2_SIZE 6
#define _TAG_IMMED2_MASK 0x3F
#define _TAG_IMMED2_ATOM ((0x0 << _TAG_IMMED1_SIZE) | _TAG_IMMED1_IMMED2)
#define _TAG_IMMED2_CATCH ((0x1 << _TAG_IMMED1_SIZE) | _TAG_IMMED1_IMMED2)
#define _TAG_IMMED2_NIL ((0x3 << _TAG_IMMED1_SIZE) | _TAG_IMMED1_IMMED2)
/*
* HEADER representation:
*
* aaaaaaaaaaaaaaaaaaaaaaaaaatttt00 arity:26, tag:4
*
* HEADER tags:
*
* 0000 ARITYVAL
* 0001 BINARY_AGGREGATE |
* 001x BIGNUM with sign bit |
* 0100 REF |
* 0101 FUN | THINGS
* 0110 FLONUM |
* 0111 EXPORT |
* 1000 REFC_BINARY | |
* 1001 HEAP_BINARY | BINARIES |
* 1010 SUB_BINARY | |
* 1011 Not used
* 1100 EXTERNAL_PID | |
* 1101 EXTERNAL_PORT | EXTERNAL THINGS |
* 1110 EXTERNAL_REF | |
* 1111 Not used
*
* COMMENTS:
*
* - The tag is zero for arityval and non-zero for thing headers.
* - A single bit differentiates between positive and negative bignums.
* - If more tags are needed, the REF and and EXTERNAL_REF tags could probably
* be combined to one tag.
*
* XXX: globally replace XXX_SUBTAG with TAG_HEADER_XXX
*/
#define ARITYVAL_SUBTAG (0x0 << _TAG_PRIMARY_SIZE) /* TUPLE */
#define BIN_MATCHSTATE_SUBTAG (0x1 << _TAG_PRIMARY_SIZE)
#define POS_BIG_SUBTAG (0x2 << _TAG_PRIMARY_SIZE) /* BIG: tags 2&3 */
#define NEG_BIG_SUBTAG (0x3 << _TAG_PRIMARY_SIZE) /* BIG: tags 2&3 */
#define _BIG_SIGN_BIT (0x1 << _TAG_PRIMARY_SIZE)
#define REF_SUBTAG (0x4 << _TAG_PRIMARY_SIZE) /* REF */
#define FUN_SUBTAG (0x5 << _TAG_PRIMARY_SIZE) /* FUN */
#define FLOAT_SUBTAG (0x6 << _TAG_PRIMARY_SIZE) /* FLOAT */
#define EXPORT_SUBTAG (0x7 << _TAG_PRIMARY_SIZE) /* FLOAT */
#define _BINARY_XXX_MASK (0x3 << _TAG_PRIMARY_SIZE)
#define REFC_BINARY_SUBTAG (0x8 << _TAG_PRIMARY_SIZE) /* BINARY */
#define HEAP_BINARY_SUBTAG (0x9 << _TAG_PRIMARY_SIZE) /* BINARY */
#define SUB_BINARY_SUBTAG (0xA << _TAG_PRIMARY_SIZE) /* BINARY */
#define EXTERNAL_PID_SUBTAG (0xC << _TAG_PRIMARY_SIZE) /* EXTERNAL_PID */
#define EXTERNAL_PORT_SUBTAG (0xD << _TAG_PRIMARY_SIZE) /* EXTERNAL_PORT */
#define EXTERNAL_REF_SUBTAG (0xE << _TAG_PRIMARY_SIZE) /* EXTERNAL_REF */
#define _TAG_HEADER_ARITYVAL (TAG_PRIMARY_HEADER|ARITYVAL_SUBTAG)
#define _TAG_HEADER_FUN (TAG_PRIMARY_HEADER|FUN_SUBTAG)
#define _TAG_HEADER_POS_BIG (TAG_PRIMARY_HEADER|POS_BIG_SUBTAG)
#define _TAG_HEADER_NEG_BIG (TAG_PRIMARY_HEADER|NEG_BIG_SUBTAG)
#define _TAG_HEADER_FLOAT (TAG_PRIMARY_HEADER|FLOAT_SUBTAG)
#define _TAG_HEADER_EXPORT (TAG_PRIMARY_HEADER|EXPORT_SUBTAG)
#define _TAG_HEADER_REF (TAG_PRIMARY_HEADER|REF_SUBTAG)
#define _TAG_HEADER_REFC_BIN (TAG_PRIMARY_HEADER|REFC_BINARY_SUBTAG)
#define _TAG_HEADER_HEAP_BIN (TAG_PRIMARY_HEADER|HEAP_BINARY_SUBTAG)
#define _TAG_HEADER_SUB_BIN (TAG_PRIMARY_HEADER|SUB_BINARY_SUBTAG)
#define _TAG_HEADER_EXTERNAL_PID (TAG_PRIMARY_HEADER|EXTERNAL_PID_SUBTAG)
#define _TAG_HEADER_EXTERNAL_PORT (TAG_PRIMARY_HEADER|EXTERNAL_PORT_SUBTAG)
#define _TAG_HEADER_EXTERNAL_REF (TAG_PRIMARY_HEADER|EXTERNAL_REF_SUBTAG)
#define _TAG_HEADER_BIN_MATCHSTATE (TAG_PRIMARY_HEADER|BIN_MATCHSTATE_SUBTAG)
#define _TAG_HEADER_MASK 0x3F
#define _HEADER_SUBTAG_MASK 0x3C /* 4 bits for subtag */
#define _HEADER_ARITY_OFFS 6
#define header_is_transparent(x) \
(((x) & (_HEADER_SUBTAG_MASK)) == ARITYVAL_SUBTAG)
#define header_is_arityval(x) (((x) & _HEADER_SUBTAG_MASK) == ARITYVAL_SUBTAG)
#define header_is_thing(x) (!header_is_transparent((x)))
#define header_is_bin_matchstate(x) ((((x) & (_HEADER_SUBTAG_MASK)) == BIN_MATCHSTATE_SUBTAG))
#define _CPMASK 0x3
/* immediate object access methods */
#define is_immed(x) (((x) & _TAG_PRIMARY_MASK) == TAG_PRIMARY_IMMED1)
#define is_not_immed(x) (!is_immed((x)))
#define IS_CONST(x) is_immed((x))
#if TAG_PRIMARY_IMMED1 == _TAG_PRIMARY_MASK
#define is_both_immed(x,y) is_immed(((x)&(y)))
#else
#define is_both_immed(x,y) (is_immed((x)) && is_immed((y)))
#endif
#define is_not_both_immed(x,y) (!is_both_immed((x),(y)))
/* boxed object access methods */
#if HALFWORD_HEAP
#define _is_taggable_pointer(x) (((UWord)(x) & (CHECK_POINTER_MASK | 0x3)) == 0)
#define _boxed_precond(x) (is_boxed(x))
#else
#define _is_taggable_pointer(x) (((Uint)(x) & 0x3) == 0)
#define _boxed_precond(x) (is_boxed(x))
#endif
#define _is_aligned(x) (((Uint)(x) & 0x3) == 0)
#define _unchecked_make_boxed(x) ((Uint) COMPRESS_POINTER(x) + TAG_PRIMARY_BOXED)
_ET_DECLARE_CHECKED(Eterm,make_boxed,Eterm*);
#define make_boxed(x) _ET_APPLY(make_boxed,(x))
#if 1
#define _is_not_boxed(x) ((x) & (_TAG_PRIMARY_MASK-TAG_PRIMARY_BOXED))
#define _unchecked_is_boxed(x) (!_is_not_boxed((x)))
_ET_DECLARE_CHECKED(int,is_boxed,Eterm)
#define is_boxed(x) _ET_APPLY(is_boxed,(x))
#else
#define is_boxed(x) (((x) & _TAG_PRIMARY_MASK) == TAG_PRIMARY_BOXED)
#endif
#define _unchecked_boxed_val(x) ((Eterm*) EXPAND_POINTER(((x) - TAG_PRIMARY_BOXED)))
_ET_DECLARE_CHECKED(Eterm*,boxed_val,Eterm);
#define boxed_val(x) _ET_APPLY(boxed_val,(x))
/* cons cell ("list") access methods */
#define _unchecked_make_list(x) ((Uint) COMPRESS_POINTER(x) + TAG_PRIMARY_LIST)
_ET_DECLARE_CHECKED(Eterm,make_list,Eterm*);
#define make_list(x) _ET_APPLY(make_list,(x))
#if 1
#define _unchecked_is_not_list(x) ((x) & (_TAG_PRIMARY_MASK-TAG_PRIMARY_LIST))
_ET_DECLARE_CHECKED(int,is_not_list,Eterm)
#define is_not_list(x) _ET_APPLY(is_not_list,(x))
#define is_list(x) (!is_not_list((x)))
#else
#define is_list(x) (((x) & _TAG_PRIMARY_MASK) == TAG_PRIMARY_LIST)
#define is_not_list(x) (!is_list((x)))
#endif
#if HALFWORD_HEAP
#define _list_precond(x) (is_list(x))
#else
#define _list_precond(x) (is_list(x))
#endif
#define _unchecked_list_val(x) ((Eterm*) EXPAND_POINTER((x) - TAG_PRIMARY_LIST))
_ET_DECLARE_CHECKED(Eterm*,list_val,Eterm);
#define list_val(x) _ET_APPLY(list_val,(x))
#define CONS(hp, car, cdr) \
(CAR(hp)=(car), CDR(hp)=(cdr), make_list(hp))
#define CAR(x) ((x)[0])
#define CDR(x) ((x)[1])
/* generic tagged pointer (boxed or list) access methods */
#define _unchecked_ptr_val(x) ((Eterm*) EXPAND_POINTER((x) & ~((Uint) 0x3)))
#define ptr_val(x) _unchecked_ptr_val((x)) /*XXX*/
#define _unchecked_offset_ptr(x,offs) ((x)+((offs)*sizeof(Eterm)))
#define offset_ptr(x,offs) _unchecked_offset_ptr(x,offs) /*XXX*/
/* fixnum ("small") access methods */
#if defined(ARCH_64) && !HALFWORD_HEAP
#define SMALL_BITS (64-4)
#define SMALL_DIGITS (17)
#else
#define SMALL_BITS (28)
#define SMALL_DIGITS (8)
#endif
#define MAX_SMALL ((1L << (SMALL_BITS-1))-1)
#define MIN_SMALL (-(1L << (SMALL_BITS-1)))
#define make_small(x) (((Uint)(x) << _TAG_IMMED1_SIZE) + _TAG_IMMED1_SMALL)
#define is_small(x) (((x) & _TAG_IMMED1_MASK) == _TAG_IMMED1_SMALL)
#define is_not_small(x) (!is_small((x)))
#define is_byte(x) (((x) & ((~(Uint)0 << (_TAG_IMMED1_SIZE+8)) + _TAG_IMMED1_MASK)) == _TAG_IMMED1_SMALL)
#define is_valid_bit_size(x) (((Sint)(x)) >= 0 && ((x) & 0x7F) == _TAG_IMMED1_SMALL)
#define is_not_valid_bit_size(x) (!is_valid_bit_size((x)))
#define MY_IS_SSMALL(x) (((Uint) (((x) >> (SMALL_BITS-1)) + 1)) < 2)
#define _unchecked_unsigned_val(x) ((x) >> _TAG_IMMED1_SIZE)
_ET_DECLARE_CHECKED(Uint,unsigned_val,Eterm)
#define unsigned_val(x) _ET_APPLY(unsigned_val,(x))
#define _unchecked_signed_val(x) ((Sint)(x) >> _TAG_IMMED1_SIZE)
_ET_DECLARE_CHECKED(Sint,signed_val,Eterm)
#define signed_val(x) _ET_APPLY(signed_val,(x))
#if _TAG_IMMED1_SMALL == 0x0F
#define is_both_small(x,y) (((x) & (y) & _TAG_IMMED1_MASK) == _TAG_IMMED1_SMALL)
#elif _TAG_IMMED1_SMALL == 0x00
#define is_both_small(x,y) ((((x)|(y)) & _TAG_IMMED1_MASK) == _TAG_IMMED1_SMALL)
#else
#define is_both_small(x,y) (is_small(x) && is_small(y))
#endif
/* NIL access methods */
#define NIL ((~((Uint) 0) << _TAG_IMMED2_SIZE) | _TAG_IMMED2_NIL)
#define is_nil(x) ((x) == NIL)
#define is_not_nil(x) ((x) != NIL)
#define MAX_ATOM_INDEX (~(~((Uint) 0) << (sizeof(Uint)*8 - _TAG_IMMED2_SIZE)))
/* atom access methods */
#define make_atom(x) ((Eterm)(((x) << _TAG_IMMED2_SIZE) + _TAG_IMMED2_ATOM))
#define is_atom(x) (((x) & _TAG_IMMED2_MASK) == _TAG_IMMED2_ATOM)
#define is_not_atom(x) (!is_atom(x))
#define _unchecked_atom_val(x) ((x) >> _TAG_IMMED2_SIZE)
_ET_DECLARE_CHECKED(Uint,atom_val,Eterm)
#define atom_val(x) _ET_APPLY(atom_val,(x))
/* header (arityval or thing) access methods */
#define _make_header(sz,tag) ((Uint)(((sz) << _HEADER_ARITY_OFFS) + (tag)))
#define is_header(x) (((x) & _TAG_PRIMARY_MASK) == TAG_PRIMARY_HEADER)
#define _unchecked_header_arity(x) ((x) >> _HEADER_ARITY_OFFS)
_ET_DECLARE_CHECKED(Uint,header_arity,Eterm)
#define header_arity(x) _ET_APPLY(header_arity,(x))
/* arityval access methods */
#define make_arityval(sz) _make_header((sz),_TAG_HEADER_ARITYVAL)
#define is_arity_value(x) (((x) & _TAG_HEADER_MASK) == _TAG_HEADER_ARITYVAL)
#define is_not_arity_value(x) (!is_arity_value((x)))
#define _unchecked_arityval(x) _unchecked_header_arity((x))
_ET_DECLARE_CHECKED(Uint,arityval,Eterm)
#define arityval(x) _ET_APPLY(arityval,(x))
/* thing access methods */
#define is_thing(x) (is_header((x)) && header_is_thing((x)))
#define _unchecked_thing_arityval(x) _unchecked_header_arity((x))
_ET_DECLARE_CHECKED(Uint,thing_arityval,Eterm)
#define thing_arityval(x) _ET_APPLY(thing_arityval,(x))
#define _unchecked_thing_subtag(x) ((x) & _HEADER_SUBTAG_MASK)
_ET_DECLARE_CHECKED(Uint,thing_subtag,Eterm)
#define thing_subtag(x) _ET_APPLY(thing_subtag,(x))
/*
* Magic non-value object.
* Used as function return error and "absent value" indicator
* in the original runtime system. The new runtime system also
* uses it as forwarding marker for CONS cells.
*
* This value is 0 in the original runtime system, which unfortunately
* promotes sloppy programming practices. It also prevents some useful
* tag assignment schemes, e.g. using a 2-bit tag 00 for FIXNUM.
*
* To help find code which makes unwarranted assumptions about zero,
* we now use a non-zero bit-pattern in debug mode.
*/
#if ET_DEBUG
#define THE_NON_VALUE _make_header(0,_TAG_HEADER_FLOAT)
#else
#define THE_NON_VALUE (0)
#endif
#define is_non_value(x) ((x) == THE_NON_VALUE)
#define is_value(x) ((x) != THE_NON_VALUE)
/* binary object access methods */
#define is_binary_header(x) (((x) & (_TAG_HEADER_MASK-_BINARY_XXX_MASK)) == _TAG_HEADER_REFC_BIN)
#define make_binary(x) make_boxed((Eterm*)(x))
#define is_binary(x) (is_boxed((x)) && is_binary_header(*boxed_val((x))))
#define is_not_binary(x) (!is_binary((x)))
#define _unchecked_binary_val(x) _unchecked_boxed_val((x))
_ET_DECLARE_CHECKED(Eterm*,binary_val,Eterm)
#define binary_val(x) _ET_APPLY(binary_val,(x))
/* process binaries stuff (special case of binaries) */
#define HEADER_PROC_BIN _make_header(PROC_BIN_SIZE-1,_TAG_HEADER_REFC_BIN)
/* fun & export objects */
#define is_any_fun(x) (is_fun((x)) || is_export((x)))
#define is_not_any_fun(x) (!is_any_fun((x)))
/* fun objects */
#define HEADER_FUN _make_header(ERL_FUN_SIZE-2,_TAG_HEADER_FUN)
#define is_fun_header(x) ((x) == HEADER_FUN)
#define make_fun(x) make_boxed((Eterm*)(x))
#define is_fun(x) (is_boxed((x)) && is_fun_header(*boxed_val((x))))
#define is_not_fun(x) (!is_fun((x)))
#define _unchecked_fun_val(x) _unchecked_boxed_val((x))
_ET_DECLARE_CHECKED(Eterm*,fun_val,Eterm)
#define fun_val(x) _ET_APPLY(fun_val,(x))
/* export access methods */
#define make_export(x) make_boxed((x))
#define is_export(x) (is_boxed((x)) && is_export_header(*boxed_val((x))))
#define is_not_export(x) (!is_export((x)))
#define _unchecked_export_val(x) _unchecked_boxed_val(x)
_ET_DECLARE_CHECKED(Eterm*,export_val,Eterm)
#define export_val(x) _ET_APPLY(export_val,(x))
#define is_export_header(x) ((x) == HEADER_EXPORT)
#if HALFWORD_HEAP
#define HEADER_EXPORT _make_header(2,_TAG_HEADER_EXPORT)
#else
#define HEADER_EXPORT _make_header(1,_TAG_HEADER_EXPORT)
#endif
/* bignum access methods */
#define make_pos_bignum_header(sz) _make_header((sz),_TAG_HEADER_POS_BIG)
#define make_neg_bignum_header(sz) _make_header((sz),_TAG_HEADER_NEG_BIG)
#define _is_bignum_header(x) (((x) & (_TAG_HEADER_MASK-_BIG_SIGN_BIT)) == _TAG_HEADER_POS_BIG)
#define _unchecked_bignum_header_is_neg(x) ((x) & _BIG_SIGN_BIT)
_ET_DECLARE_CHECKED(int,bignum_header_is_neg,Eterm)
#define bignum_header_is_neg(x) _ET_APPLY(bignum_header_is_neg,(x))
#define _unchecked_bignum_header_neg(x) ((x) | _BIG_SIGN_BIT)
_ET_DECLARE_CHECKED(Eterm,bignum_header_neg,Eterm)
#define bignum_header_neg(x) _ET_APPLY(bignum_header_neg,(x))
#define _unchecked_bignum_header_arity(x) _unchecked_header_arity((x))
_ET_DECLARE_CHECKED(Uint,bignum_header_arity,Eterm)
#define bignum_header_arity(x) _ET_APPLY(bignum_header_arity,(x))
#define BIG_ARITY_MAX ((1 << 19)-1)
#define make_big(x) make_boxed((x))
#define is_big(x) (is_boxed((x)) && _is_bignum_header(*boxed_val((x))))
#define is_not_big(x) (!is_big((x)))
#define _unchecked_big_val(x) _unchecked_boxed_val((x))
_ET_DECLARE_CHECKED(Eterm*,big_val,Eterm)
#define big_val(x) _ET_APPLY(big_val,(x))
/* flonum ("float") access methods */
#if defined(ARCH_64) && !HALFWORD_HEAP
#define HEADER_FLONUM _make_header(1,_TAG_HEADER_FLOAT)
#else
#define HEADER_FLONUM _make_header(2,_TAG_HEADER_FLOAT)
#endif
#define make_float(x) make_boxed((x))
#define is_float(x) (is_boxed((x)) && *boxed_val((x)) == HEADER_FLONUM)
#define is_not_float(x) (!is_float(x))
#define _unchecked_float_val(x) _unchecked_boxed_val((x))
_ET_DECLARE_CHECKED(Eterm*,float_val,Eterm)
#define float_val(x) _ET_APPLY(float_val,(x))
/* Float definition for byte and word access */
typedef double ieee754_8;
typedef union float_def
{
ieee754_8 fd;
byte fb[sizeof(ieee754_8)];
Uint16 fs[sizeof(ieee754_8) / sizeof(Uint16)];
Uint32 fw[sizeof(ieee754_8) / sizeof(Uint32)];
#if defined(ARCH_64) && !HALFWORD_HEAP
Uint fdw;
#endif
} FloatDef;
#if defined(ARCH_64) && !HALFWORD_HEAP
#define GET_DOUBLE(x, f) (f).fdw = *(float_val(x)+1)
#define PUT_DOUBLE(f, x) *(x) = HEADER_FLONUM, \
*((x)+1) = (f).fdw
#define GET_DOUBLE_DATA(p, f) (f).fdw = *((Uint *) (p))
#define PUT_DOUBLE_DATA(f,p) *((Uint *) (p)) = (f).fdw
#else
#define GET_DOUBLE(x, f) (f).fw[0] = *(float_val(x)+1), \
(f).fw[1] = *(float_val(x)+2)
#define PUT_DOUBLE(f, x) *(x) = HEADER_FLONUM, \
*((x)+1) = (f).fw[0], \
*((x)+2) = (f).fw[1]
#define GET_DOUBLE_DATA(p, f) (f).fw[0] = *((Uint *) (p)),\
(f).fw[1] = *(((Uint *) (p))+1)
#define PUT_DOUBLE_DATA(f,p) *((Uint *) (p)) = (f).fw[0],\
*(((Uint *) (p))+1) = (f).fw[1]
#endif
#define DOUBLE_DATA_WORDS (sizeof(ieee754_8)/sizeof(Eterm))
#define FLOAT_SIZE_OBJECT (DOUBLE_DATA_WORDS+1)
/* tuple access methods */
#define make_tuple(x) make_boxed((x))
#define is_tuple(x) (is_boxed((x)) && is_arity_value(*boxed_val((x))))
#define is_not_tuple(x) (!is_tuple((x)))
#define is_tuple_arity(x, a) \
(is_boxed((x)) && *boxed_val((x)) == make_arityval((a)))
#define is_not_tuple_arity(x, a) (!is_tuple_arity((x),(a)))
#define _unchecked_tuple_val(x) _unchecked_boxed_val(x)
_ET_DECLARE_CHECKED(Eterm*,tuple_val,Eterm)
#define tuple_val(x) _ET_APPLY(tuple_val,(x))
#define TUPLE0(t) \
((t)[0] = make_arityval(0), \
make_tuple(t))
#define TUPLE1(t,e1) \
((t)[0] = make_arityval(1), \
(t)[1] = (e1), \
make_tuple(t))
#define TUPLE2(t,e1,e2) \
((t)[0] = make_arityval(2), \
(t)[1] = (e1), \
(t)[2] = (e2), \
make_tuple(t))
#define TUPLE3(t,e1,e2,e3) \
((t)[0] = make_arityval(3), \
(t)[1] = (e1), \
(t)[2] = (e2), \
(t)[3] = (e3), \
make_tuple(t))
#define TUPLE4(t,e1,e2,e3,e4) \
((t)[0] = make_arityval(4), \
(t)[1] = (e1), \
(t)[2] = (e2), \
(t)[3] = (e3), \
(t)[4] = (e4), \
make_tuple(t))
#define TUPLE5(t,e1,e2,e3,e4,e5) \
((t)[0] = make_arityval(5), \
(t)[1] = (e1), \
(t)[2] = (e2), \
(t)[3] = (e3), \
(t)[4] = (e4), \
(t)[5] = (e5), \
make_tuple(t))
#define TUPLE6(t,e1,e2,e3,e4,e5,e6) \
((t)[0] = make_arityval(6), \
(t)[1] = (e1), \
(t)[2] = (e2), \
(t)[3] = (e3), \
(t)[4] = (e4), \
(t)[5] = (e5), \
(t)[6] = (e6), \
make_tuple(t))
#define TUPLE7(t,e1,e2,e3,e4,e5,e6,e7) \
((t)[0] = make_arityval(7), \
(t)[1] = (e1), \
(t)[2] = (e2), \
(t)[3] = (e3), \
(t)[4] = (e4), \
(t)[5] = (e5), \
(t)[6] = (e6), \
(t)[7] = (e7), \
make_tuple(t))
#define TUPLE8(t,e1,e2,e3,e4,e5,e6,e7,e8) \
((t)[0] = make_arityval(8), \
(t)[1] = (e1), \
(t)[2] = (e2), \
(t)[3] = (e3), \
(t)[4] = (e4), \
(t)[5] = (e5), \
(t)[6] = (e6), \
(t)[7] = (e7), \
(t)[8] = (e8), \
make_tuple(t))
/* This macro get Size bits starting at low order position Pos
and adjusts the bits to the right
bits are numbered from 0 - (sizeof(Uint)*8-1) */
#define _GETBITS(X,Pos,Size) (((X) >> (Pos)) & ~(~((Uint) 0) << (Size)))
/*
* Observe! New layout for pids, ports and references in R9 (see also note
* in erl_node_container_utils.h).
*/
/*
* Creation in node specific data (pids, ports, refs)
*/
#define _CRE_SIZE 2
/* MAX value for the creation field in pid, port and reference */
#define MAX_CREATION (1 << _CRE_SIZE)
/*
* PID layout (internal pids):
*
* |3 3 2 2 2 2 2 2|2 2 2 2 1 1 1 1|1 1 1 1 1 1 | |
* |1 0 9 8 7 6 5 4|3 2 1 0 9 8 7 6|5 4 3 2 1 0 9 8|7 6 5 4 3 2 1 0|
* | | | | |
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |n n n n n n n n n n n n n n n n n n n n n n n n n n n n|0 0|1 1|
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
*
* n : number
*
* Old pid layout:
*
* |3 3 2 2 2 2 2 2|2 2 2 2 1 1 1 1|1 1 1 1 1 1 | |
* |1 0 9 8 7 6 5 4|3 2 1 0 9 8 7 6|5 4 3 2 1 0 9 8|7 6 5 4 3 2 1 0|
* | | | | |
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |s s s|n n n n n n n n n n n n n n n|N N N N N N N N|c c|0 0|1 1|
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
*
* s : serial
* n : number
* c : creation
* N : node number
*
*/
#define _PID_R9_SER_SIZE 3
#define _PID_SER_SIZE (_PID_DATA_SIZE - _PID_NUM_SIZE)
#define _PID_NUM_SIZE 15
#define _PID_DATA_SIZE 28
#define _PID_DATA_SHIFT (_TAG_IMMED1_SIZE)
#define _GET_PID_DATA(X) _GETBITS((X),_PID_DATA_SHIFT,_PID_DATA_SIZE)
#define _GET_PID_NUM(X) _GETBITS((X),0,_PID_NUM_SIZE)
#define _GET_PID_SER(X) _GETBITS((X),_PID_NUM_SIZE,_PID_SER_SIZE)
#define make_pid_data(Ser, Num) \
((Uint) ((Ser) << _PID_NUM_SIZE | (Num)))
#define make_internal_pid(X) \
((Eterm) (((X) << _PID_DATA_SHIFT) | _TAG_IMMED1_PID))
#define is_internal_pid(x) (((x) & _TAG_IMMED1_MASK) == _TAG_IMMED1_PID)
#define is_not_internal_pid(x) (!is_internal_pid((x)))
#define _unchecked_internal_pid_data(x) _GET_PID_DATA((x))
_ET_DECLARE_CHECKED(Uint,internal_pid_data,Eterm)
#define internal_pid_data(x) _ET_APPLY(internal_pid_data,(x))
#define _unchecked_internal_pid_node(x) erts_this_node
_ET_DECLARE_CHECKED(struct erl_node_*,internal_pid_node,Eterm)
#define internal_pid_node(x) _ET_APPLY(internal_pid_node,(x))
#define internal_pid_number(x) _GET_PID_NUM(internal_pid_data((x)))
#define internal_pid_serial(x) _GET_PID_SER(internal_pid_data((x)))
#define internal_pid_data_words(x) (1)
/*
* PORT layout (internal ports):
*
* |3 3 2 2 2 2 2 2|2 2 2 2 1 1 1 1|1 1 1 1 1 1 | |
* |1 0 9 8 7 6 5 4|3 2 1 0 9 8 7 6|5 4 3 2 1 0 9 8|7 6 5 4 3 2 1 0|
* | | | | |
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |n n n n n n n n n n n n n n n n n n n n n n n n n n n n|0 1|1 1|
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
*
* n : number
*
* Old port layout:
*
* |3 3 2 2 2 2 2 2|2 2 2 2 1 1 1 1|1 1 1 1 1 1 | |
* |1 0 9 8 7 6 5 4|3 2 1 0 9 8 7 6|5 4 3 2 1 0 9 8|7 6 5 4 3 2 1 0|
* | | | | |
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |N N N N N N N N|n n n n n n n n n n n n n n n n n n|c c|0 1|1 1|
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
*
* s : serial
* n : number
* c : creation
* N : node number
*
*/
#define _PORT_R9_NUM_SIZE 18
#define _PORT_NUM_SIZE _PORT_DATA_SIZE
#define _PORT_DATA_SIZE 28
#define _PORT_DATA_SHIFT (_TAG_IMMED1_SIZE)
#define _GET_PORT_DATA(X) _GETBITS((X),_PORT_DATA_SHIFT,_PORT_DATA_SIZE)
#define _GET_PORT_NUM(X) _GETBITS((X), 0, _PORT_NUM_SIZE)
#define make_internal_port(X) \
((Eterm) (((X) << _PORT_DATA_SHIFT) | _TAG_IMMED1_PORT))
#define is_internal_port(x) (((x) & _TAG_IMMED1_MASK) == _TAG_IMMED1_PORT)
#define is_not_internal_port(x) (!is_internal_port(x))
#define _unchecked_internal_port_data(x) _GET_PORT_DATA((x))
_ET_DECLARE_CHECKED(Uint,internal_port_data,Eterm)
#define internal_port_data(x) _ET_APPLY(internal_port_data,(x))
#define internal_port_number(x) _GET_PORT_NUM(internal_port_data((x)))
#define _unchecked_internal_port_node(x) erts_this_node
_ET_DECLARE_CHECKED(struct erl_node_*,internal_port_node,Eterm)
#define internal_port_node(x) _ET_APPLY(internal_port_node,(x))
#define internal_port_data_words(x) (1)
/*
* Ref layout (internal references):
*
* |3 3 2 2 2 2 2 2|2 2 2 2 1 1 1 1|1 1 1 1 1 1 | |
* |1 0 9 8 7 6 5 4|3 2 1 0 9 8 7 6|5 4 3 2 1 0 9 8|7 6 5 4 3 2 1 0|
* | | | | |
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1|0 1 0 0|0 0| Thing
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |0 0 0 0 0 0 0 0 0 0 0 0 0 0|r r r r r r r r r r r r r r r r r r| Data 0
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |r r r r r r r r r r r r r r r r r r r r r r r r r r r r r r r r| Data 1
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |r r r r r r r r r r r r r r r r r r r r r r r r r r r r r r r r| Data 2
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
*
*
* r : reference number
* c : creation
*
*
* Old "heap ref" layout:
*
*
* |3 3 2 2 2 2 2 2|2 2 2 2 1 1 1 1|1 1 1 1 1 1 | |
* |1 0 9 8 7 6 5 4|3 2 1 0 9 8 7 6|5 4 3 2 1 0 9 8|7 6 5 4 3 2 1 0|
* | | | | |
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1|0 1 0 0|0 0| Thing
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |N N N N N N N N|0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0|c c|0 1 1 1| Head
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |0 0 0 0 0 0 0 0 0 0 0 0 0 0|r r r r r r r r r r r r r r r r r r| Word 0
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |r r r r r r r r r r r r r r r r r r r r r r r r r r r r r r r r| Word 1
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |r r r r r r r r r r r r r r r r r r r r r r r r r r r r r r r r| Word 2
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
*
* r : reference number
* c : creation
* N : node index
*
* Old "one-word ref" layout:
*
* |3 3 2 2 2 2 2 2|2 2 2 2 1 1 1 1|1 1 1 1 1 1 | |
* |1 0 9 8 7 6 5 4|3 2 1 0 9 8 7 6|5 4 3 2 1 0 9 8|7 6 5 4 3 2 1 0|
* | | | | |
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |N N N N N N N N|r r r r r r r r r r r r r r r r r r|c c|T T T T|
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
*
* r : reference number
* c : creation
* N : node index
*
*/
#define _REF_NUM_SIZE 18
/* Old maximum number of references in the system */
#define MAX_REFERENCE (1 << _REF_NUM_SIZE)
#define REF_MASK (~(~((Uint)0) << _REF_NUM_SIZE))
#define ERTS_MAX_REF_NUMBERS 3
#define ERTS_REF_NUMBERS ERTS_MAX_REF_NUMBERS
#if defined(ARCH_64) && !HALFWORD_HEAP
# define ERTS_REF_WORDS (ERTS_REF_NUMBERS/2 + 1)
# define ERTS_REF_32BIT_WORDS (ERTS_REF_NUMBERS+1)
#else
# define ERTS_REF_WORDS ERTS_REF_NUMBERS
# define ERTS_REF_32BIT_WORDS ERTS_REF_NUMBERS
#endif
typedef struct {
Eterm header;
union {
Uint32 ui32[ERTS_REF_32BIT_WORDS];
Uint ui[ERTS_REF_WORDS];
} data;
} RefThing;
#define REF_THING_SIZE (sizeof(RefThing)/sizeof(Uint))
#define REF_THING_HEAD_SIZE (sizeof(Eterm)/sizeof(Uint))
#define make_ref_thing_header(DW) \
_make_header((DW)+REF_THING_HEAD_SIZE-1,_TAG_HEADER_REF)
#if defined(ARCH_64) && !HALFWORD_HEAP
/*
* Ref layout on a 64-bit little endian machine:
*
* 63 31 0
* +--------------+--------------+
* | Thing word |
* +--------------+--------------+
* | Data 0 | 32-bit arity |
* +--------------+--------------+
* | Data 2 | Data 1 |
* +--------------+--------------+
*
* Data is stored as an Uint32 array with 32-bit arity as first number.
*/
#define write_ref_thing(Hp, R0, R1, R2) \
do { \
((RefThing *) (Hp))->header = make_ref_thing_header(ERTS_REF_WORDS); \
((RefThing *) (Hp))->data.ui32[0] = ERTS_REF_NUMBERS; \
((RefThing *) (Hp))->data.ui32[1] = (R0); \
((RefThing *) (Hp))->data.ui32[2] = (R1); \
((RefThing *) (Hp))->data.ui32[3] = (R2); \
} while (0)
#else
#define write_ref_thing(Hp, R0, R1, R2) \
do { \
((RefThing *) (Hp))->header = make_ref_thing_header(ERTS_REF_WORDS); \
((RefThing *) (Hp))->data.ui32[0] = (R0); \
((RefThing *) (Hp))->data.ui32[1] = (R1); \
((RefThing *) (Hp))->data.ui32[2] = (R2); \
} while (0)
#endif
#define is_ref_thing_header(x) (((x) & _TAG_HEADER_MASK) == _TAG_HEADER_REF)
#define make_internal_ref(x) make_boxed((Eterm*)(x))
#define _unchecked_ref_thing_ptr(x) \
((RefThing*) _unchecked_internal_ref_val(x))
#define ref_thing_ptr(x) \
((RefThing*) internal_ref_val(x))
#define is_internal_ref(x) \
(_unchecked_is_boxed((x)) && is_ref_thing_header(*boxed_val((x))))
#define is_not_internal_ref(x) \
(!is_internal_ref((x)))
#define _unchecked_internal_ref_val(x) _unchecked_boxed_val((x))
_ET_DECLARE_CHECKED(Eterm*,internal_ref_val,Eterm)
#define internal_ref_val(x) _ET_APPLY(internal_ref_val,(x))
#define _unchecked_internal_ref_data_words(x) \
(_unchecked_thing_arityval(*_unchecked_internal_ref_val(x)))
_ET_DECLARE_CHECKED(Uint,internal_ref_data_words,Eterm)
#define internal_ref_data_words(x) _ET_APPLY(internal_ref_data_words,(x))
#define _unchecked_internal_ref_data(x) (_unchecked_ref_thing_ptr(x)->data.ui32)
_ET_DECLARE_CHECKED(Uint32*,internal_ref_data,Eterm)
#define internal_ref_data(x) _ET_APPLY(internal_ref_data,(x))
#define _unchecked_internal_ref_node(x) erts_this_node
_ET_DECLARE_CHECKED(struct erl_node_*,internal_ref_node,Eterm)
#define internal_ref_node(x) _ET_APPLY(internal_ref_node,(x))
/*
*
* External thing layout (external pids, ports, and refs):
*
* |3 3 2 2 2 2 2 2|2 2 2 2 1 1 1 1|1 1 1 1 1 1 | |
* |1 0 9 8 7 6 5 4|3 2 1 0 9 8 7 6|5 4 3 2 1 0 9 8|7 6 5 4 3 2 1 0|
* | | | | |
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |A A A A A A A A A A A A A A A A A A A A A A A A A A|t t t t|0 0| Thing
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |N N N N N N N N N N N N N N N N N N N N N N N N N N N N N N N N| Next
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |E E E E E E E E E E E E E E E E E E E E E E E E E E E E E E E E| ErlNode
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* |X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X| Data 0
* +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
* . . .
* . . .
* . . .
*
* A : Arity
* t : External pid thing tag (1100)
* t : External port thing tag (1101)
* t : External ref thing tag (1110)
* N : Next (external thing) pointer
* E : ErlNode pointer
* X : Type specific data
*
* External pid and port layout:
* External pids and ports only have one data word (Data 0) which has
* the same layout as internal pids resp. internal ports.
*
* External refs layout:
* External refs has the same layout for the data words as in the internal
* ref.
*
*/
typedef struct external_thing_ {
/* ----+ */
Eterm header; /* | */
struct external_thing_ *next; /* > External thing head */
struct erl_node_ *node; /* | */
/* ----+ */
union {
Uint32 ui32[1];
Uint ui[1];
} data;
} ExternalThing;
#define EXTERNAL_THING_HEAD_SIZE (sizeof(ExternalThing)/sizeof(Uint) - 1)
#define make_external_pid_header(DW) \
_make_header((DW)+EXTERNAL_THING_HEAD_SIZE-1,_TAG_HEADER_EXTERNAL_PID)
#define is_external_pid_header(x) \
(((x) & _TAG_HEADER_MASK) == _TAG_HEADER_EXTERNAL_PID)
#define make_external_port_header(DW) \
_make_header((DW)+EXTERNAL_THING_HEAD_SIZE-1,_TAG_HEADER_EXTERNAL_PORT)
#define is_external_port_header(x) \
(((x) & _TAG_HEADER_MASK) == _TAG_HEADER_EXTERNAL_PORT)
#define make_external_ref_header(DW) \
_make_header((DW)+EXTERNAL_THING_HEAD_SIZE-1,_TAG_HEADER_EXTERNAL_REF)
#define is_external_ref_header(x) \
(((x) & _TAG_HEADER_MASK) == _TAG_HEADER_EXTERNAL_REF)
#define is_external_header(x) \
(((x) & (_TAG_HEADER_MASK-_BINARY_XXX_MASK)) == _TAG_HEADER_EXTERNAL_PID)
#define is_external(x) \
(is_boxed((x)) && is_external_header(*boxed_val((x))))
#define is_external_pid(x) \
(is_boxed((x)) && is_external_pid_header(*boxed_val((x))))
#define is_external_port(x) \
(is_boxed((x)) && is_external_port_header(*boxed_val((x))))
#define is_external_ref(x) \
(_unchecked_is_boxed((x)) && is_external_ref_header(*boxed_val((x))))
#define _unchecked_is_external(x) \
(_unchecked_is_boxed((x)) && is_external_header(*_unchecked_boxed_val((x))))
#define is_not_external(x) (!is_external((x)))
#define is_not_external_pid(x) (!is_external_pid((x)))
#define is_not_external_port(x) (!is_external_port((x)))
#define is_not_external_ref(x) (!is_external_ref((x)))
#define make_external(x) make_boxed((Eterm *) (x))
#define make_external_pid make_external
#define make_external_port make_external
#define make_external_ref make_external
#define _unchecked_external_val(x) _unchecked_boxed_val((x))
_ET_DECLARE_CHECKED(Eterm*,external_val,Eterm)
#define external_val(x) _ET_APPLY(external_val,(x))
#define external_thing_ptr(x) ((ExternalThing *) external_val((x)))
#define _unchecked_external_thing_ptr(x) \
((ExternalThing *) _unchecked_external_val((x)))
#define _unchecked_external_data_words(x) \
(_unchecked_thing_arityval(_unchecked_external_thing_ptr((x))->header) \
+ (1 - EXTERNAL_THING_HEAD_SIZE))
_ET_DECLARE_CHECKED(Uint,external_data_words,Eterm)
#define external_data_words(x) _ET_APPLY(external_data_words,(x))
#define _unchecked_external_data(x) (_unchecked_external_thing_ptr((x))->data.ui)
#define _unchecked_external_node(x) (_unchecked_external_thing_ptr((x))->node)
#define external_data(x) (external_thing_ptr((x))->data.ui)
#define external_node(x) (external_thing_ptr((x))->node)
#define _unchecked_external_pid_data_words(x) \
_unchecked_external_data_words((x))
_ET_DECLARE_CHECKED(Uint,external_pid_data_words,Eterm)
#define external_pid_data_words(x) _ET_APPLY(external_pid_data_words,(x))
#define _unchecked_external_pid_data(x) _unchecked_external_data((x))[0]
_ET_DECLARE_CHECKED(Uint,external_pid_data,Eterm)
#define external_pid_data(x) _ET_APPLY(external_pid_data,(x))
#define _unchecked_external_pid_node(x) _unchecked_external_node((x))
_ET_DECLARE_CHECKED(struct erl_node_*,external_pid_node,Eterm)
#define external_pid_node(x) _ET_APPLY(external_pid_node,(x))
#define external_pid_number(x) _GET_PID_NUM(external_pid_data((x)))
#define external_pid_serial(x) _GET_PID_SER(external_pid_data((x)))
#define _unchecked_external_port_data_words(x) \
_unchecked_external_data_words((x))
_ET_DECLARE_CHECKED(Uint,external_port_data_words,Eterm)
#define external_port_data_words(x) _ET_APPLY(external_port_data_words,(x))
#define _unchecked_external_port_data(x) _unchecked_external_data((x))[0]
_ET_DECLARE_CHECKED(Uint,external_port_data,Eterm)
#define external_port_data(x) _ET_APPLY(external_port_data,(x))
#define _unchecked_external_port_node(x) _unchecked_external_node((x))
_ET_DECLARE_CHECKED(struct erl_node_*,external_port_node,Eterm)
#define external_port_node(x) _ET_APPLY(external_port_node,(x))
#define external_port_number(x) _GET_PORT_NUM(external_port_data((x)))
#define _unchecked_external_ref_data_words(x) \
_unchecked_external_data_words((x))
_ET_DECLARE_CHECKED(Uint,external_ref_data_words,Eterm)
#define external_ref_data_words(x) _ET_APPLY(external_ref_data_words,(x))
#define _unchecked_external_ref_data(x) (_unchecked_external_thing_ptr((x))->data.ui32)
_ET_DECLARE_CHECKED(Uint32*,external_ref_data,Eterm)
#define external_ref_data(x) _ET_APPLY(external_ref_data,(x))
#define _unchecked_external_ref_node(x) _unchecked_external_node((x))
_ET_DECLARE_CHECKED(struct erl_node_*,external_ref_node,Eterm)
#define external_ref_node(x) _ET_APPLY(external_ref_node,(x))
/* number tests */
#define is_integer(x) (is_small(x) || is_big(x))
#define is_not_integer(x) (!is_integer(x))
#define is_number(x) (is_integer(x) || is_float(x))
#define SMALL_MINUS_ONE make_small(-1)
#define SMALL_ZERO make_small(0)
#define SMALL_ONE make_small(1)
#define ENULL 0
/* on some architectures CP contains labels which are not aligned */
#ifdef NOT_ALIGNED
#error "fix yer arch, like"
#endif
#define _unchecked_make_cp(x) ((Eterm) COMPRESS_POINTER(x))
_ET_DECLARE_CHECKED(Eterm,make_cp,UWord*);
#define make_cp(x) _ET_APPLY(make_cp,(x))
#define is_not_CP(x) ((x) & _CPMASK)
#define is_CP(x) (!is_not_CP(x))
#define _unchecked_cp_val(x) ((UWord*) EXPAND_POINTER(x))
_ET_DECLARE_CHECKED(UWord*,cp_val,Eterm);
#define cp_val(x) _ET_APPLY(cp_val,(x))
#define make_catch(x) (((x) << _TAG_IMMED2_SIZE) | _TAG_IMMED2_CATCH)
#define is_catch(x) (((x) & _TAG_IMMED2_MASK) == _TAG_IMMED2_CATCH)
#define is_not_catch(x) (!is_catch(x))
#define _unchecked_catch_val(x) ((x) >> _TAG_IMMED2_SIZE)
_ET_DECLARE_CHECKED(Uint,catch_val,Eterm)
#define catch_val(x) _ET_APPLY(catch_val,(x))
#define make_blank(X) ((X) = NIL)
/*
* Overloaded tags.
*
* SMALL = 15
* ATOM/NIL=7
*
* Note that the two least significant bits in SMALL/ATOM/NIL always are 3;
* thus, we can distinguish register from literals by looking at only these
* two bits.
*/
#define X_REG_DEF 0
#define Y_REG_DEF 1
#define R_REG_DEF 2
#define beam_reg_tag(x) ((x) & 3)
#define make_rreg() R_REG_DEF
#define make_xreg(ix) (((ix) * sizeof(Eterm)) | X_REG_DEF)
#define make_yreg(ix) (((ix) * sizeof(Eterm)) | Y_REG_DEF)
#define _is_xreg(x) (beam_reg_tag(x) == X_REG_DEF)
#define _is_yreg(x) (beam_reg_tag(x) == Y_REG_DEF)
#define _unchecked_x_reg_offset(R) ((R) - X_REG_DEF)
_ET_DECLARE_CHECKED(Uint,x_reg_offset,Uint)
#define x_reg_offset(R) _ET_APPLY(x_reg_offset,(R))
#define _unchecked_y_reg_offset(R) ((R) - Y_REG_DEF)
_ET_DECLARE_CHECKED(Uint,y_reg_offset,Uint)
#define y_reg_offset(R) _ET_APPLY(y_reg_offset,(R))
#define reg_index(R) ((R) / sizeof(Eterm))
#define _unchecked_x_reg_index(R) ((R) >> 2)
_ET_DECLARE_CHECKED(Uint,x_reg_index,Uint)
#define x_reg_index(R) _ET_APPLY(x_reg_index,(R))
#define _unchecked_y_reg_index(R) ((R) >> 2)
_ET_DECLARE_CHECKED(Uint,y_reg_index,Uint)
#define y_reg_index(R) _ET_APPLY(y_reg_index,(R))
/*
* Backwards compatibility definitions:
* - #define virtal *_DEF constants with values that fit term order:
* number < atom < ref < fun < port < pid < tuple < nil < cons < binary
* - tag_val_def() function generates virtual _DEF tag
* - not_eq_tags() and NUMBER_CODE() defined in terms
* of the tag_val_def() function
*/
#define BINARY_DEF 0x0
#define LIST_DEF 0x1
#define NIL_DEF 0x2
#define TUPLE_DEF 0x3
#define PID_DEF 0x4
#define EXTERNAL_PID_DEF 0x5
#define PORT_DEF 0x6
#define EXTERNAL_PORT_DEF 0x7
#define EXPORT_DEF 0x8
#define FUN_DEF 0x9
#define REF_DEF 0xa
#define EXTERNAL_REF_DEF 0xb
#define ATOM_DEF 0xc
#define FLOAT_DEF 0xd
#define BIG_DEF 0xe
#define SMALL_DEF 0xf
#if ET_DEBUG
extern unsigned tag_val_def_debug(Eterm, const char*, unsigned);
#define tag_val_def(x) tag_val_def_debug((x),__FILE__,__LINE__)
#else
extern unsigned tag_val_def(Eterm);
#endif
#define not_eq_tags(X,Y) (tag_val_def((X)) ^ tag_val_def((Y)))
#define NUMBER_CODE(x,y) ((tag_val_def(x) << 4) | tag_val_def(y))
#define _NUMBER_CODE(TX,TY) ((TX << 4) | TY)
#define SMALL_SMALL _NUMBER_CODE(SMALL_DEF,SMALL_DEF)
#define SMALL_BIG _NUMBER_CODE(SMALL_DEF,BIG_DEF)
#define SMALL_FLOAT _NUMBER_CODE(SMALL_DEF,FLOAT_DEF)
#define BIG_SMALL _NUMBER_CODE(BIG_DEF,SMALL_DEF)
#define BIG_BIG _NUMBER_CODE(BIG_DEF,BIG_DEF)
#define BIG_FLOAT _NUMBER_CODE(BIG_DEF,FLOAT_DEF)
#define FLOAT_SMALL _NUMBER_CODE(FLOAT_DEF,SMALL_DEF)
#define FLOAT_BIG _NUMBER_CODE(FLOAT_DEF,BIG_DEF)
#define FLOAT_FLOAT _NUMBER_CODE(FLOAT_DEF,FLOAT_DEF)
#endif /* __ERL_TERM_H */